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Benchmarking the fundamental parameters of Ap stars with optical long-baseline interferometric measurements
K. Perraut, M. Cunha, A. Romanovskaya, D. Shulyak, T. Ryabchikova, V.
Hocdé, N. Nardetto, D. Mourard, A. Meilland, F. Morand, et al.
To cite this version:
K. Perraut, M. Cunha, A. Romanovskaya, D. Shulyak, T. Ryabchikova, et al.. Benchmarking the fundamental parameters of Ap stars with optical long-baseline interferometric measurements. Astron- omy and Astrophysics - A&A, EDP Sciences, 2020, 642, pp.A101. �10.1051/0004-6361/202038753�.
�hal-02963288�
Astronomy &
Astrophysics
https://doi.org/10.1051/0004-6361/202038753
© K. Perraut et al. 2020
Benchmarking the fundamental parameters of Ap stars with optical long-baseline interferometric measurements ?
K. Perraut 1 , M. Cunha 2,3 , A. Romanovskaya 4 , D. Shulyak 5 , T. Ryabchikova 4 , V. Hocdé 6 , N. Nardetto 6 , D. Mourard 6 , A. Meilland 6 , F. Morand 6 , I. Tallon-Bosc 7 , C. Farrington 8 , and C. Lanthermann 9
1
Univ. Grenoble Alpes, CNRS, IPAG, 38000 Grenoble, France e-mail: karine.perraut@univ-grenoble-alpes.fr
2
Instituto de Astrofísica e Ciências do Espaço, Universidade do Porto, CAUP, Rua das Estrelas, 4150-762 Porto, Portugal
3
School of Physics and Astronomy, University of Birmingham, Birmingham, B15 2TT, UK
4
Institute of Astronomy, Russian Academy of Sciences, Pyatnitskaya 48, 119017 Moscow, Russia
5
Max-Planck Institute fur Sonnensystemforschung, Justus-von-Liebig-Weg 3, 37077 Göttingen, Germany
6
Université Côte d’Azur, Observatoire de la Côte d’Azur, CNRS, Laboratoire Lagrange, France
7
Univ. Lyon, Univ. Lyon1, ENS de Lyon, CNRS, Centre de Recherche Astrophysique de Lyon UMR5574, 69230 Saint-Genis-Laval, France
8
CHARA Array, Mount Wilson Observatory, 91023 Mount Wilson CA, USA
9
Instituut voor Sterrenkunde, Katholieke Universiteit Leuven, 3001 Leuven, Belgium Received 25 June 2020 / Accepted 31 August 2020
ABSTRACT
Context. The variety of physical processes at play in chemically peculiar stars makes it difficult to determine their fundamental parameters. In particular, for the magnetic ones, called Ap stars, the strong magnetic fields and the induced spotted stellar surfaces may lead to biased effective temperatures when these values are derived through spectro-photometry.
Aims. We propose to benefit from the exquisite angular resolution provided by long-baseline interferometry in the visible to determine the accurate angular diameters of a number of Ap stars, and thus estimate their radii by a method that is as independent as possible of atmospheric models.
Methods. We used the visible spectrograph VEGA at the CHARA interferometric array to complete the sample of Ap stars currently observable with this technique. We estimated the angular diameter and radius of six new targets. We estimated their bolometric flux based solely on observational spectroscopic and photometric data to derive nearly model-independent luminosities and effective temperatures.
Results. We extend to 14 the number of Ap stars for which interferometric angular diameters have been measured. The fundamental parameters we derived for the complete Ap sample are compared with those obtained through a self-consistent spectroscopic analysis.
Based on a model fitting approach of high-resolution spectra and spectro-photometric observations over a wide wavelength range, this method takes into account the anomalous chemical composition of the atmospheres and the inhomogeneous vertical distribution for different chemical elements. Regarding both the radii and the effective temperatures, the derived values from our interferometric observations and from self-consistent modelling are consistent within better than 2σ for nine targets out of ten. We thus benchmark nine Ap stars for effective temperatures ranging from 7200 and 9100 K, and luminosities ranging between 7 L and 86 L .
Conclusions. These results will be key for the future derivation of accurate radii and other fundamental parameters of fainter peculiar stars for which both the sensitivity and the angular resolution of the current interferometers are not sufficient. Within the context of the observations of Ap stars with the Transiting Exoplanet Survey Satellite (TESS), these interferometric measurements are crucial for testing the mechanism of pulsation excitation at work in these peculiar stars. In particular, our interferometric measurements provide accurate locations in the Hertzsprung-Russell diagram for hot Ap stars among which pulsations may be searched for with TESS, putting to test the blue edge of the theoretical instability strip. These accurate locations could be used to derive masses and ages of these stars through a specific grid of models, and to test correlations between the properties of these peculiar stars and their evolutionary state.
Key words. methods: observational – techniques: high angular resolution – techniques: interferometric – stars: fundamental parameters
1. Introduction
Magnetic fields are detected in a large variety of stars throughout the spectral type range and are known to play a crucial role during star formation and evolution. They have an impact on numerous physical phenomena at play within the stars and their environments such as accretion, mass loss, turbulence, and pulsations, and on some fundamental stellar properties such
?
CHARA/VEGA observations.
as rotational speed and stellar chemical abundances (Donati
& Landstreet 2009). One of the best examples of how stellar magnetic fields impact stellar surface properties is found in the chemically peculiar Ap stars. These are stars of spectral types A and B, characterized by strong and large-scale organized magnetic fields typically of several kG, and abundance inho- mogeneities of a few orders of magnitude with respect to solar values, leading to spotted surfaces (Preston 1974). They also exhibit low rotational speeds (≤100 km s −1 ) supposed to be due to magnetic braking (Mathys 2017). Owing to their abnormal A101, page 1 of 13
Open Access article,published by EDP Sciences, under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0),
Table 1. Stellar properties for the complete Ap sample, with T
effand L derived from Kochukhov & Bagnulo (2006).
# HD B V Sp. type T e ff [K] L [L ]
1 4778 6.16 6.15 A3Vp 9980 32.4
2 24712 (a) 6.00 6.32 A9p 7190 7.4
3 108662 5.18 5.2 A0p 10 500 64.6
4 108945 5.47 5.4 A2pv 8950 51.3
5 118022 (b) 4.94 4.96 Ap 9060 28.8 6 120198 5.66 5.7 B9pe 10 540 44.7 7 128898 (c) 3.19 3.43 A7p 7670 11.0 8 137909 (d) 3.68 3.97 F2p 7430 27.5
9 153882 6.26 6.3 B9p 9730 100
10 176232 (e) 5.89 6.14 A7p 7930 20.9 11 188041 ( f ) 5.81 5.6 A5p 8430 35.5 12 201601 (g) 4.68 4.94 A9p 7620 12.6 13 204411 ( f ) 5.37 5.3 A4pv 8750 89.1
14 220825 4.94 4.9 A2pv 9080 22.4
Notes. The objects previously observed are in italics, and the corre- sponding references are given in the Notes.
References.
(a)Perraut et al. (2016);
(b)Perraut et al. (2015);
(c)Bruntt et al. (2008);
(d)Bruntt et al. (2010);
(e)Perraut et al. (2013);
(f)
Romanovskaya et al. (2019b);
(g)Perraut et al. (2011).
stellar surfaces, the determination of their fundamental parame- ters by (spectro)-photometry can be biased. Using long-baseline interferometry to provide accurate angular diameters of these particular stars appears to be a promising approach to over- coming the difficulties in deriving accurate global parameters.
However, this approach is also very challenging because of the stars’ small angular size (less than 1 mas).
The first interferometric observations of the largest Ap star α Cir by Bruntt et al. (2008) were performed with the VLTI (Glindemann et al. 2003). Then several campaigns on the bright- est and the largest Ap stars were conducted with the CHARA array (Ten Brummelaar et al. 2010) since this interferometric array with its baselines B as long as 330 m and its visible instrumentation allows targets as small as λ/2B = 0.2 mas to be partially resolved. To date, accurate angular diameters have been determined by optical long-baseline interferometry for eight Ap stars (given in italics in Table 1). In this paper we report on the angular diameter measurements of six additional Ap stars in the northern hemisphere, which extends the Ap sample for which we derive stellar radii by interferometry to 14 (hereafter referred to as the complete Ap sample). Our objective is to cover a wide range of luminosities and effective temperatures, and thus to probe the theoretical instability strip where the sub-category of Ap stars exhibiting pulsations, the rapidly oscillating Ap (roAp) stars, are expected (Balmforth et al. 2001; Cunha 2002; Cunha et al. 2019). The effective temperatures of our complete Ap sam- ple range from about 7200 to 10 550 K and the luminosities from about 7 to 100 L (Table 1). Ultra-precise photometric light curves will be available for most known Ap stars once the NASA Transiting Exoplanet Survey Satellite (TESS) mission (Ricker et al. 2014) completes its first two years of science observa- tions. Having accurate stellar parameters and the necessary data to search for the presence of pulsations in the sample of stars considered in this work is an important step towards testing the- oretical predictions for the driving of pulsations in roAp stars (Cunha et al. 2020).
Our aim is to derive stellar radii and effective tempera- tures that are as independent of stellar models as possible. Once
validated these models could be used to derive radii of fainter and/or farther stars for which the sensitivity and/or the angular resolution of interferometry are currently not sufficient. When looking at the Renson catalogue of Ap, HgMn, and Am stars (Renson & Manfroid 2009), most of the targets are located in the southern hemisphere and the histograms of the stars for both hemispheres is centred on Vmag = 9 (Fig. 1, left), which is out of reach of the sensitivity of the current visible interferometric instrumentations whose best performance corresponds to a limit- ing magnitude of about 8–8.5 in R band (Ireland et al. 2008; Ligi et al. 2013). In addition, when looking at the expected angular sizes of the targets that are brighter than this limit, we find that only a few of them are above 0.2 mas (Fig. 1, right), a value that is already very challenging to measure.
We present the interferometric observations and the angu- lar diameters and radii derived from our last CHARA/VEGA observations in Sect. 2. We then use (spectro-)photometric data to compute the bolometric fluxes based solely on observational data in Sect. 3. In Sect. 4 we compute the stellar effective temperatures and luminosities and discuss our results in Sect. 5.
2. Last interferometric observations of Ap stars with VEGA/CHARA
2.1. Observations
During the 2016–2018 period, we observed six Ap stars with dif- ferent telescope triplets of the CHARA array (Ten Brummelaar et al. 2010) and the VEGA visible instrument (Mourard et al.
2009). We operated VEGA in parallel with the K-band CLIMB beam combiner acting as a fringe tracker (Sturmann et al. 2010).
We used the medium spectral resolution of VEGA ( R ∼ 6000) and recorded fringes on spectral bands centred around ∼700 or ∼ 730 nm, depending on the targets. We interleaved our target observations with calibrator observations, following the sequence calibrator-target-calibrator, with 40 or 60 blocks of 2500 short exposures (of 10 ms) per star. We swapped from one star to another every 30 min to correctly calibrate the instrumen- tal transfer function. We used the SearchCal software (Bonneau et al. 2006) proposed by the JMMC 1 to find suitable calibra- tors. The observation log is given in Appendix A along with the spatial frequency coverage for all targets.
2.2. Data processing
We used the standard VEGA reduction pipeline (Mourard et al.
2009) to compute the squared visibilities over spectral bands of 15 or 20 nm according to the width of water absorption lines in the spectrum. Such large bandwidths lead to a mean spectral resolution of about 40, and our visibility measurements are thus mainly sensitive to the stellar photosphere. We followed the same processing as described in our previous papers (Perraut et al.
2011, 2013, 2015, 2016) to compute raw squared visibility for each block of 2500 individual frames. Even though we recorded data with telescope triplets, we cannot retrieve closure phases on our targets since the signal-to-noise ratio on this observ- able is strongly limited by the saturation limit of the VEGA photon-counting detectors (see Fig. 4 in Mourard et al. 2012).
2.3. Angular diameters and radii
We followed the same approach as in our previous papers to calibrate the target squared visibilities V 2 by using the angular
1
Available at www.jmmc.fr/searchcal
Fig. 1. Left: Vmag histograms of the Renson targets (Renson & Manfroid 2009) for the southern and northern hemispheres. Right: expected angular diameter as a function of the brightest Ap stars of the northern (orange circles) and southern (blue triangles) hemispheres. The yellow area corresponds to the sensitivity and the angular resolution of the visible instrumentations of the CHARA array.
Table 2. Uniform-disc angular diameters in the R band of our calibrators from the JSDC catalogues.
Calibrator V–K θ UD [mas]
HD 4335 −0.08 0.184 ± 0.013 HD 108765 0.25 0.257 ± 0.019 HD 118214 −0.04 0.230 ± 0.016 HD 120874 0.26 0.194 ± 0.014 HD 151862 0.05 0.19 ± 0.015 HD 156653 0.076 0.18 ± 0.016 HD 217186 0.21 0.188 ± 0.013 HD 223855 0.05 0.170 ± 0.012 HD 224103 −0.12 0.163 ± 0.011 HD 224926 −0.31 0.222 ± 0.016
diameters of the calibrators provided by the JSDC catalogues (Bonneau et al. 2006; Bourges et al. 2017) to compute the trans- fer function. We adopted a conservative uncertainty of 7% on the uniform angular diameter (Table 2). Our calibrators are stars of A-B spectral types. For these early-type stars, since the JSDC diameter estimation exhibits discrepancies with the surface brightness–colour relations (SBCRs) for V–K < 0, we adopted the uniform diameters provided by the JSDC2 catalogue which shows a better consistency with SBCRs (see Fig. 3d in Challouf et al. 2014). The calibrated squared visibility curves versus spatial frequencies are given in Fig. 2.
We determined the uniform-disc angular diameter θ UD of our targets in the R band using the model fitting tool LITpro 2 (Tallon- Bosc et al. 2008), and the limb-darkened angular diameters θ LD
considering the linear limb-darkening coefficients in the R band from the Claret tables (Claret & Bloemen 2011) when using an effective temperature range in agreement with the values in Table 1 and a surface gravity log g between 4 and 4.5.
Stellar radii R (in solar radius, R ) can be derived from our angular diameter measurements θ LD (in mas), and the parallaxes π P (in seconds of arc) through the formula
R = θ LD 9.305 × π P
. (1)
2
www.jmmc.fr/litpro_page.htm
We used the parallaxes π P from the second Gaia DR2 release (Gaia Collaboration 2018) and computed the error bars on π P
using the formula provided by Lindegren et al. (2018) at the IAU colloquium:
σ ext = q
k 2 σ 2 i + σ 2 s . (2)
Here σ i is the internal error provided in the Gaia DR2 catalogue, k = 1.08, and σ s = 0.021 mas is the systematic error for G < 13.
All the angular diameters, the parallaxes we consider, and the radii are given in Table 4.
3. Bolometric fluxes
We follow the same approach as in our previous papers to derive the bolometric fluxes from observational spectral energy distri- butions (SEDs; e.g. Perraut et al. 2011, 2013, 2015, 2016). So, in addition to the six Ap targets presented in the last section, we also computed the SED of HD 188041 and HD 204411, which was not done in Romanovskaya et al. (2019b).
3.1. Building the spectral energy distributions
To compute the bolometric fluxes from the SED, we gathered the following spectro-photometric data:
– For wavelengths in the range 1265 Å < λ < 3180 Å, we used rebinned spectra from the Sky Survey Telescope obtained at the IUE Newly Extracted Spectra (INES) data archive 3 . We removed all bad pixels and measurements with negative flux using the quality flag (Garhart et al. 1997);
– We collected the photometric data from TD1 (Thompson et al. 1978) at 1565, 1965, 2365, and 2740 Å;
– For wavelengths in the visible range we used flux- calibrated ELODIE (Prugniel & Soubiran 2001; Prugniel et al.
2007) and/or MILES (Sánchez-Blázquez et al. 2006) spec- tra, along with spectroscopic observations with the Boller &
Chivens long-slit spectrograph mounted at the 2.1 m telescope at the Observatorio Astronómico Nacional (OAN) at San Pedro Mártir in Mexico (see Romanovskaya et al. 2019b for the data description and processing).
3
http://sdc.cab.inta-csic.es/cgi-ines/IUEdbsMY
Fig. 2. Squared VEGA visibilities (circles) and uniform-disc models for the best fits (orange solid lines) and for the angular diameters at ±1σ (grey dotted lines).
– For wavelengths in the range 3300 Å < λ < 7850 Å we also collected the photometric data from the Adelman catalogue (Adelman et al. 1989) and converted the flux as described in our Appendix B. We used these data to calibrate the visible spectrum of HD 108662 in flux;
– At longer wavelengths (in the J, H, and K bands) we col- lected the photometric data from the 2MASS All Sky Catalog of point sources 4 (Cutri et al. 2003) and corrected for the filter responses using the zeropoints from Cohen et al. (2003).
At the lower wavelength end of the spectral distribution, we performed a linear interpolation on logarithmic scale between
4
http://irsa.ipac.caltech.edu/applications/Gator/
912 and 1842 Å, assuming zero flux at 912 Å. At the higher wave- length end of the spectral distribution, we performed a linear interpolation on logarithmic scale using the 2MASS magnitudes and assuming zero flux at 1.6 × 10 6 Å.
All the datasets we considered are found in Table 3, and the corresponding spectral distributions are given in Fig. 3. The vis- ible spectra appear to have the same shape for all our targets, but scaling in amplitude with the V magnitude; they all are in agree- ment with the Adelman measurements when available. For the lower wavelengths (between 1265 and 3180 Å) the few spectra we collected exhibit complex features; when both datasets are avail- able, the INES ones and the TD1 ones are in good agreement.
Finally, all the Adelman datasets display a flux that does not vary
Table 3. Spectroscopic and photometric datasets used for the bolometric flux computation with the corresponding spectral ranges.
Target INES TD1 Adelman ( + ) Visible 2MASS f bol [erg cm −2 s −1 ] f bol [erg cm −2 s −1 ]
spectra This work from modelling
HD 4778 [1265 ... 3180] Y – [3900 ... 6800] (a) J, H, K 0.97 ± 0.10 × 10 −7 – HD 108662 [1265 ... 3180] – [3300 ... 7100] [4000 ... 6800] (a) J, H, K 2.24 ± 0.21× 10 −7 (•) 2.53 ± 0.15 × 10 −7 HD 108945 [1265 ... 3180] Y [3300 ... 7100] [3900 ... 6800] (a) J, H, K 1.68 ± 0.15 × 10 −7 – HD 120198 [1265 ... 3180] Y [3300 ... 7100] [3725 ... 7210] (b) J, H, K 1.62 ± 0.13 × 10 −7 –
HD 153882 – Y [3390 ... 7850] [3535 ... 7405] (c) J, H, K 0.81 ± 0.06× 10 −7 0.79 ± 0.04 × 10 −7 HD 188041 [1977 ... 3180] Y [3390 ... 7850] [3535 ... 7405] (c) J, H, K 1.34 ± 0.16 × 10 −7 1.34 ± 0.25 ×10 −7 HD 204411 – Y [3300 ... 6800] [3720 ... 7215] (b) J, H, K 1.90 ± 0.15× 10 −7 1.84 ± 0.15 ×10 −7 HD 220825 – – [3300 ... 7850] [3725 ... 7215] (b) J, H, K 2.30 ± 0.17 ×10 −7 –
Notes. The bolometric fluxes obtained from our work and from self-consistent atmosphere modelling are given in the last two columns. See text for details.
(+)Adelman data are photometric values collected over the optical range. Visible spectra:
(a)ELODIE;
(b)OAN;
(c)MILES.
(•)We accounted for the 1.32 scale factor of the IUE flux, as explained in Sect. 3.1.
by more than 4% over the 3400–3700 Å wavelength range (here- after called constant flux). This corresponds to the Balmer jump, which is very pronounced for the A-type stars. We noticed that the IUE flux for HD 108662 is too low compared to this Adel- man constant flux (Fig. 3, right, first row), which might come from flux losses of the IUE satellite for bright sources. To match IUE flux with Adelman UV flux, the IUE flux needs to be scaled up by a factor of 1.32 (Romanovskaya et al. 2020b).
3.2. Estimating the bolometric fluxes
Three targets have a complete SED (HD 108662, HD 108945, and HD 120198) and their bolometric flux values can be deter- mined by computing the area under the curve of this distribution.
When spectra and photometric data are both available in a spec- tral range, we always used the spectra to compute the area under the SED.
For the objects for which the (spectro-)photometric data do not cover the full spectral range, we used the spectro-photometry dataset coming from the complete target sample to devise a way to estimate, for each star, the flux in wavelength ranges where data are missing. This was done by establishing the correlations between the different flux data, i.e. the TD1 flux integrated over different wavelength intervals, the Adelman constant flux, and the B and V magnitudes, as described in Appendix B. In practice we proceeded as follows:
– for HD 4778, for which no Adelman data are available, we used the linear relation we found between the constant flux and the B magnitude (Fig. B.1) to estimate a constant flux of 0.99 × 10 −11 erg cm −2 s −1 Å −1 (white stars in Fig. 3, top left).
Using the linear relation derived from the V magnitude led to the same constant flux within an accuracy better than 4%. We then computed the bolometric flux from flux integration.
– for HD 153882 and HD 204411 the INES spectra are miss- ing, but TD1 data are available (blue triangles in Fig. 3, first column, third and fourth rows, respectively). For all the targets for which we have TD1 and INES spectra, we computed the integrated flux from 1975 to 3180 Å and showed that it strongly linearly correlates with the TD1 flux at 2365 Å (regression coef- ficient of 0.97; blue symbols and line on Fig. B.2). We used the derived linear law to determine an integrated flux of 7.9 × 10 −9 erg cm −2 s −1 for HD 153882 and of 1.46 × 10 −8 erg cm −2 s −1 for HD 204411 over the [1975 Å; 3180 Å] range. We also estimated this integrated flux by considering the correlation with the Adelman constant flux for the targets for which
we have both INES and Adelman datasets (regression coeffi- cient of 0.7; orange symbols and line in Fig. B.2). With this approach, we estimated an integrated flux over the [1975 Å;
3180 Å] range of 9.7 ×10 −9 erg cm −2 s −1 for HD 153882 and of 1.58 × 10 −8 erg cm −2 s −1 for HD 204411. The agreement between the two approaches is better than 8% for HD 204411 and of the order of 20% for HD 153882. In the following we used the flux values obtained with the first method since the linear regression coefficient in that case is very close to 1.
– for HD 153882, HD 188041, and HD 204411, the INES spectra over the [1265 Å; 1975 Å] range are missing, but TD1 data are available. We proceeded as before. The flux integrated between 1265 and 1975 Å was correlated with the TD1 flux at 1965 Å (regression coefficient of 0.90; Fig. B.3).
We then used this linear law to estimate an integrated flux over the [1265 Å; 1975 Å] range of 2.5 × 10 −9 erg cm −2 s −1 for HD 153882, 5.1 × 10 −9 erg cm −2 s −1 for HD 188041, and 7.1 × 10 −9 erg cm −2 s −1 for HD 204411.
– for HD 220825 the situation is different since we do not have TD1 data and we could not apply the same methods as before. We estimated the integrated flux for the [1975 Å;
3180 Å] range by using its linear correlation with the Adelman constant flux (Fig. B.2). We obtained an integrated flux of 3.1 × 10 −8 erg cm −2 s −1 for HD 220825. We studied for all our targets the correlation between the integrated fluxes over the [1265 Å;
1975 Å] range and over the [1975 Å; 3180 Å] range and derived a linear law (regression coefficient of 0.82; Fig. B.4). We used this linear law to estimate an integrated flux over the [1265 Å;
1975 Å] range of 1.3 × 10 −8 erg cm −2 s −1 for HD 220825.
As in our previous papers, we estimated the uncertainty asso- ciated with the bolometric flux by considering the following conservative uncertainties for each contribution: 3% uncertainty on the flux computed from the ELODIE, MILES, or OAN spec- trum; 10% on the flux computed from the combined INES spectra; and 15% on the flux derived from interpolations and/or estimations from correlations. These largest uncertainties are on the fluxes over the lowest wavelength range, which generally cor- respond to about 12–15% of the total flux, and always to less than 25%.
3.3. Comparison with atmospheric models
The bolometric fluxes we obtain for our new targets are listed
in Table 3. We derived uncertainties on the bolometric fluxes
Fig. 3. Spectral energy distributions:
UV–EUV INES (grey) and visible (orange) spectra, TD1 (blue triangles), Adelman (purple stars) and 2MASS (red circles) photometries. The dashed lines correspond to the interpolations.
The insets are zoomed-in images of the UV–EUV and visible domains.
between 7 and 12%. We compared our values with the bolomet- ric fluxes derived from a self-consistent spectroscopic analysis, when available. The latter approach is based on model fitting of spectro-photometric observations over a wide wavelength range, including the same INES, TD1, Adelman, and 2MASS datasets as ours. This method includes the modelling of the anomalous
chemical composition of the atmospheres of these peculiar stars and takes into account the inhomogeneous vertical distribution for different chemical elements. Model atmosphere calculations are conducted with the LLMODELS code (Shulyak et al. 2004).
Through an iterative process, a theoretical SED is produced and
compared to the observed one; the radius is a free parameter
Table 4. Limb-darkened angular diameters in the R band derived from interferometric measurements, Gaia DR2 parallaxes, radii, effective temperatures, and luminosities derived from interferometric measurements for the complete Ap sample.
Interferometric observations Modelling
# HD θ LD π P R L T e ff R T e ff hB s i
[mas] [mas] [R ] [L ] [K] [R ] [K] [kG]
1 4778 0.204 ± 0.008 9.32 ± 0.10 2.36 ± 0.12 34.9 ± 4.3 9135 ± 400 2.6 (a)
2 24712 0.335 ± 0.009 20.62 ± 0.09 1.75 ± 0.05 7.6 ± 1.2 7235 ± 280 1.75 ± 0.04 7250 ± 100 (b) 3.1 (c) 3 108662 0.328 ± 0.009 13.54 ± 0.24 2.59 ± 0.12 38.1 ± 4.9 8880 ± 330 2.09 ± 0.10 10 225 ± 100 (d) 3.3 (e)
4 108945 0.315 ± 0.006 12.00 ± 0.15 2.82 ± 0.09 36.5 ± 4.2 8430 ± 270 0.1 (a)
5 118022 0.346 ± 0.006 17.16 ± 0.25 2.17 ± 0.06 28.9 ± 3.0 9100 ± 190 2.16 ± 0.02 9140 ± 30 ( f) 3.0 ( f )
6 120198 0.226 ± 0.008 10.62 ± 0.078 2.28 ± 0.10 44.9 ± 4.3 9865 ± 370 1.6 (e)
7 128898 1.105 ± 0.037 60.35 ± 0.14 (∗) 1.967 ± 0.066 10.51 ± 0.60 7420 ± 170 1.94 ± 0.01 7500 ± 130 (g) 2.0 (h) 8 137909 0.699 ± 0.017 28.60 ± 0.69 (∗) 2.63 ± 0.09 25.3 ± 2.9 7980 ± 180 2.47 ± 0.07 8100 ± 150 (i) 5.4 ( j) 9 153882 0.193 ± 0.019 5.98 ± 0.053 3.46 ± 0.37 70.8 ± 6.5 8980 ± 600 3.35 ± 0.03 9150 ± 100 (k) 3.8 (k) 10 176232 0.275 ± 0.009 13.37 ± 0.08 2.21 ± 0.08 16.9 ± 1.4 ( + ) 7900 ± 190 ( + ) 2.35 ± 0.06 7550 ± 50 (l) 1.5 (l) 11 188041 0.247 ± 0.005 11.72 ± 0.11 2.26 ± 0.05 30.5 ± 4.2 9000 ± 360 2.39 ± 0.05 8770 ± 150 (m) 3.6 (m) 12 201601 0.564 ± 0.017 28.77 ± 0.25 2.11 ± 0.07 11.0 ± 0.93 7253 ± 235 1.98 ± 0.05 7550 ± 150 ( j) 4.0 ( j) 13 204411 0.328 ± 0.004 8.33 ± 0.12 4.23 ± 0.11 85.6 ± 9.2 8520 ± 220 4.42 ± 0.07 8300 ± 150 (m) <0.8 (n)
14 220825 0.339 ± 0.005 20.44 ± 0.23 1.78 ± 0.03 17.2 ± 1.7 8790 ± 230 2.0 (e)
Notes. The last three columns give the radii and the effective temperatures as derived from self-consistent modelling and when considering the Gaia DR2 parallaxes, and the magnetic field strengths. Four targets have not been modelled yet.
(∗)For these two targets we keep the parallaxes from H IPPARCOS because of the binarity and/or the excessive brightness.
(+)We report the average values of the effective temperatures and luminosities provided in Perraut et al. (2013).
References.
(a)Glagolevskij (2019);
(b)Shulyak et al. (2009);
(c)Ryabchikova et al. (2007);
(d)Romanovskaya et al. (2020b);
(e)Kochukhov (2017);
(f)